Comparison of WRC and nozzle pro.pdf
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Transcript of Comparison of WRC and nozzle pro.pdf
© Intergraph 2014
Presented by: Ray Delaforce
Using WRC 107 and NozzlePRO FEA
1
© Intergraph 2014
History of WRC 107
Pressure vessel analysis was handled by the codes, such as: ASME Section VIII, Division 1 ASME Section VIII, Division 2 PD 5500 (British Code) EN 13445 (European Code) AD 2000 (Merkblatter) (German Code) CODAP (French Code)
They mainly concentrated on primary membrane stresses (more later)
These stresses had to be below the yield stress of the metal
Yield
ε
σ
Within this region
The strain is not to exceed about 0,2%
0,2%2
© Intergraph 2014
History of WRC 107
Example of membrane stress in a cylinder subject to internal pressure
Yield
ε
σ
Within this region
The code allowable stress is about here, below yield
In the case of nozzles subject to external loads, the stresses can be here
That is beyond the scope of the codes
Strains go beyond 0,2%
0,2%3
© Intergraph 2014
History of WRC 107
Stress analysis is really required
WRC107 was published for this purpose
WRC107 offered a graphical method of doing the stress analysis
4
Here is a typical graph:
© Intergraph 2014
History of WRC 107
Stress analysis is really required
WRC107 was published for this purpose
WRC107 offered a graphical method of doing the stress analysis
Here is a typical graph:
Many of the graphs are difficult to read – more of that later
WRC107 first published in 1965
Revised 1968 Revised 1970 Revised 1972 Revised 1979
Based upon the theoretical work of Prof. Biljaard of Cornell University
Attachments (nozzles) on cylinders and spheres only can be analysed
There are also geometric limitations
Using WRC 107 is very tedious and time consuming
PV Elite and CodeCalc make this analysis simple and fast
5
© Intergraph 2014
Let us look at some principles of stress analysis
Consider a bar subject to a tensile force
Yield
ε
σ
0,2%
Once the stress passes yield, it continues to stretch until collapse occurs
So, we could re-label the strain axis as time to collapse
TIME
Fracture !
This shows we must under normal conditions stay below yield
6
© Intergraph 2014
Let us look at some principles of stress analysis
Suppose the force were delivered by this arrangement
Yield
ε
σ
0,2% TIME
Fracture !
If the weight were heavy enough – fracture would occur
The stress is directly proportional to the load
σ = force / area thus stress is directly related to the load (force)
7
© Intergraph 2014
Let us look at some principles of stress analysis
Yield
ε
σ
0,2% TIME
Fracture !
σ = force / area thus stress is directly related to the load (force)
By definition this is a Primary Stress The Internal stress is directly related to the external load Fracture will occur as the stress increases beyond yield
The stress also exist Everywhere in the bar – membrane stress Everywhere designates the stress as a General Stress Therefore we have a General Primary Membrane stress
8
© Intergraph 2014
Let us look at some principles of stress analysis
Yield
ε
σ
0,2% TIME
Suppose now we have table under the weight to restrict its movement
The weight can only descend so far
The stress is now controlled by movement
Stress does not reach fracture, because movement is limited
The weight is NOT related to the stress. Only to the movement
9
© Intergraph 2014
Let us look at some principles of stress analysis
Yield
ε
σ
0,2% TIME
The weight is NOT related to the stress. Only to the movement
This is known as Secondary Stress Controlled by movement of another element Internal stress not related to the force in the other component Also called strain related
10
© Intergraph 2014
Let us look at some principles of stress analysis
Now we consider a Cantilever subject to un-restricted force
There is an internal bending stress in the beam
This bending stress can exist everywhere at this location
This stress has the following characteristics The internal stress is directly related to the load - Primary It exists Everywhere –General
This is a General Primary Bending stress
11
© Intergraph 2014
Let us look at some principles of stress analysis
We again restrict the motion of the weight
The bending stress is NOT directly related to the load (weight)
Yield
ε
σ
0,2% TIME
The bending strain is restricted, and does not proceed to fracture
It is strain controlled, and not load controlled
We have a Secondary bending stress
12
© Intergraph 2014
Let us look at some principles of stress analysis
Now look at this arrangement
Yield
ε
σ
0,2% TIME
The rod is heated, so it expands
Again the stress is controlled by the strain
This is also a Secondary stress – also called an Expansion stress
13
© Intergraph 2014
Let us look at some principles of stress analysis
Sum up what we have learned so far:
Primary stress Secondary stress
Directly related to the
imposed load: eg σ= F/A
Relate to the strain induced in the component – strain controlled
Often from expansion of another component –example, thermal expansion
If the load is great, failure can occur
The strain is restricted so failure does not occur
There is one more stress category we have deal with
14
© Intergraph 2014
Let us look at some principles of stress analysis
Consider a nozzle in a shell subject to an external moment
The shell deforms to accommodate the moment like this
Notice how it pulls the shell to the left, giving rise to a membrane stress
The bending stress is ignored for the moment
This stress fades away rapidly from the nozzle to shell junction
15
© Intergraph 2014
Let us look at some principles of stress analysis
Consider a nozzle in a shell subject to an external moment
The shell deforms to accommodate the moment like this
Notice how it pulls the shell to the left, giving rise to a membrane stress
This stress fades away rapidly from the nozzle to shell junction
Over this distance
That stress does not exist everywhere, therefore it is LOCAL
This is a Local Primary Membrane stress
The bending stress is treated as Secondary stress16
© Intergraph 2014
Let us look at some principles of stress analysis
Summing what we have learned so far:
ASME Section VIII, Division 2 gives them symbols
Stress type Symbol Allowable stress
General Primary Membrane
Local Primary Membrane
Primary Bending
Secondary: Local Membrane Local Bending
Pm
PL
Pb
Q
S
1,5S
1,5S
3S or 2Sy
These stresses can exist in combination
17
© Intergraph 2014
Let us look at some principles of stress analysis
Summing what we have learned so far:
ASME Section VIII, Division 2 gives them symbols
Stress type Symbol Allowable stress
These stresses can exist in combination
Pm S
1,5S
Pm + PL + PB + Q
Pm + PL + PB
Pm + PL
1,5S
3S of 2Sy
Primary
Primary + Local
Primary + Local
Primary + Local + Secondary
18
© Intergraph 2014
Let us look at some principles of stress analysis
This is the ‘Hopper’ diagram from ASME Section VIII, Division 2
19
© Intergraph 2014
WRC 107 Force and Moment Convention
Radial force P
Longitudinal force VL
Circumferential force VC
Longitudinal moment ML
Circumferential moment MC
MTP
ML
VL
VC
MC
Torsional moment MT
Nozzle removed – here is the hole
Labeling convention
AL BL
CL
AU BU
CU
DU
A BC
U = upper surface (outside)
L = lower surface (inside)
20
© Intergraph 2014
Type of Loading per normal stress analysis
Sustained load Loads that are there for long periods Pressure Weight (on an attachments)
Occasional Loads that are momentary (lasting a short time) Wind loading Seismic loading Because they are short lived – add 20% to allowable stress
Expansion Strain controlled From thermal expansion of piping Always Secondary Stresses
Operating loads These are commonly Sustained + Thermal (eg: CAESAR II)
21
© Intergraph 2014
WRC 107 Demonstration (First)
Here are the regions around the nozzle
Here are the final stress final stress Categories
S1,2S1,5S1,8S 1,8=1,2 x 1,53S
22
© Intergraph 2014
WRC 107 Does not discuss Pressure Thrust on the nozzle
dO
P
Thrust F = PπdO2/4, this can be added in PV Elite (Demo)
Before After
23
© Intergraph 2014
There is a stress concentration at the Nozzle to Shell junction
The stress increases at the junction like this:
SA
SC
SA is the average stress, SC is the increases stress
SC /SA is known as the stress concentration factor (scf)
It is usually about 3
ASME VIII, Division 2 calls the scf by the name of Pressure Index
24
© Intergraph 2014
Adding the scf (Pressure Indices) - (Demo)
SA
SC
It now FAILS, we can fix the problem be adding a re-pad (Demo)
25
© Intergraph 2014
We now have two analyses
Nozzle junction Edge of the pad
26
© Intergraph 2014
WRC107 deficiencies
It only considers 4 points around the nozzle
The method is only an approximation
We need better tools to get a better answer
The answer is FEA !
27
© Intergraph 2014
Introduction to NozzlePRO FEA analysis
Now we set the same nozzle up in NozzlePRO (Demo)
28
© Intergraph 2014
Setting the nozzle-vessel in Global Units
+y+x
A
B
C
Radial force P is in the +X direction
Radial force P
Longitudinal force VL
Circumferential force VC
Longitudinal moment ML
Circumferential moment MC
Torsional moment MT
Longitudinal force VL is in the -Y direction from B to A
Circumferential force VC is in the +Z direction from D to C
We need to know the Orientation of the Nozzle and the Vessel
+x and +y are known as Direction Cosines
We need to understand Direction Cosines
What is a direction cosine ?
29
© Intergraph 2014
What is a direction cosine ?
Let us construct a 3 dimensional world, or system
Label the 3 directions by the letters x, y and z
z
y
x
A vector can be represented by an arrow from the origin
The axes can be thought of as the corners of a box
The vector can be represented by r, defines magnitude & direction
The magnitude (length) is defined as |r|, or simply r
r
30
© Intergraph 2014
What is a direction cosine ?
These angles define the direction cosines
z
y
x
rφy
φx
φz
Now, put in the distances along the axes of the vector
az
ay
ax
The direction cosine of y is defined as cos( ) =ay
rφy
ax
r
az
rSimilarly cos( ) = , and cos( ) = φx φz
31
© Intergraph 2014
What is a direction cosine ?
Let the direction cosines be represented by Vx, Vy and Vz
z
y
x
rφy
φx
φzaz
ay
ax
Now, if Vy = 1, it follows that = 0O because cos(0O) = 1φy
Then Vx = cos( ) , Vy = cos( ) and Vz = cos( )φx φy φz
But, if Vx = 0, and Vz = 0, then = 90O and = 90Oφx φz
The vector would then point in the direction of +y
32
© Intergraph 2014
What is a direction cosine ?
Let the direction cosines be represented by Vx, Vy and Vz
z
y
x
φx=90O
az
ay
ax
Now, if Vy = 1, it follows that = 0O because cos(0O) = 1φy
Then Vx = cos( ) , Vy = cos( ) and Vz = cos( )φx φy φz
But, if Vx = 0, and Vz = 0, then = 90O and = 90Oφx φz
The vector would then point in the direction of +y
φz=90O
33
© Intergraph 2014
What is a direction cosine ?
Let the direction cosines be represented by Vx, Vy and Vz
z
y
xaz
ay
ax
If Vz = 0, Vx = 1 and Vy = 0, the vector would point along x axis
Then Vx = cos( ) , Vy = cos( ) and Vz = cos( )φx φy φz
φz=90O
φz=90O
34
© Intergraph 2014
What is a direction cosine ?
Let the direction cosines be represented by Vx, Vy and Vz
z
y
φz=90O
az
ay
ax
If Vx = 0, Vy = 0 and Vz = 1, the vector would point along z axis
Then Vx = cos( ) , Vy = cos( ) and Vz = cos( )φx φy φz
φx=90φx=90O
We just set the direction cosine to 1 for the particular direction
x
35
© Intergraph 2014
What is a direction cosine ?
We just set the direction cosine to 1 for the particular direction
+y
A
B
C
+x
36